JP3212816B2 - Combined filtration and desalination equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water treatment apparatus for performing both a filtration treatment and a desalination treatment in order to remove impurities contained in the water to be treated. A compact complex suitable as a water treatment device that treats condensate water so that it can be used again as boiler water. The present invention relates to a type filtration desalination apparatus.

[0002]

2. Description of the Related Art In a thermal power plant or a nuclear power plant, steam generated in a boiler or a nuclear reactor is sent to a condensing turbine, which drives a generator and condenses the steam in a condenser. After being guided to the apparatus and subjected to necessary processing, it is sent again to the boiler or the nuclear reactor. In general,
Such a condensate recycling system is called a condensate system.

[0003] By the way, in the configuration of a condensate treatment device provided in a condensate system of a boiling water type (BWR type) nuclear power plant (hereinafter simply referred to as a nuclear power plant), a large amount of condensate can be treated. Removal of soluble and suspended substances in condensate (mainly corrosion products generated from equipment and piping, including iron oxide, iron hydroxide, etc., called cladding) Ensure that the required water quality can be maintained over a long period of time, and if seawater used as cooling water in the condenser leaks, completely remove ions and foreign matter in the seawater and prevent it from flowing into the reactor. What can be done is an essential requirement for safe and continuous operation of the reactor.

In order to satisfy such a requirement, a recent condensate treatment apparatus for a nuclear power plant has a hollow fiber membrane filtration apparatus in which a number of hollow fiber membrane modules are arranged in a tower and a plurality of filtration towers are arranged in parallel. , And a subsequent ion-exchange type desalination apparatus in which a number of desalination towers filled with ion-exchange resin are arranged in parallel, and these are connected in series. For example, when treating condensed water of 6,600 Ton / Hr, 5 to 8 filtration towers and 3 to 8 desalination towers each having a tower diameter of about 3 m are required. The hollow fiber membrane filtration device is provided for removing the clad in the condensate water, and the ion exchange type desalination device is provided for removing the ions in the condensate water. In particular, the ion-exchange type desalination equipment must have a capacity to completely remove ions brought in from seawater in the event that seawater leaks from the condenser,
This is a determinant of the device scale.

[0005]

By the way, regarding the condensate treatment equipment of a nuclear power plant, the required installation area of the condensate treatment equipment is reduced, the whole is made compact, and the condensate treatment equipment is reduced for the following reasons. It is an urgent task to reduce the equipment cost of the facilities. First of all, taking into account the recent difficulties in locating nuclear power plants,
There is a demand to reduce the site area of the nuclear power plant as much as possible, and for that purpose, it is necessary to reduce the installation area of the condensate treatment device. Second, the condensate treatment equipment of a nuclear power plant is disposed in a building sealed with thick walls made of reinforced concrete for shielding, because it is a device for treating condensate containing radioactive materials. . This is because the construction of a reinforced concrete building requires enormous costs, and it is necessary to reduce the construction cost by reducing the size of the building containing the condensate treatment device as much as possible. Third, it is necessary to reduce the equipment cost of the condensate treatment apparatus and reduce the equipment cost of the entire nuclear power plant.

However, a conventional condensate treatment apparatus in which a hollow fiber membrane filtration apparatus and an ion exchange type desalination apparatus, which are separately installed, are connected in series, has a membrane technology capable of efficiently removing cladding in condensate water. Although it is an excellent device that takes advantage of the respective features of ion exchange technology that can efficiently remove cations and anions in condensate water, it is difficult to significantly reduce the installation area and equipment costs for the following reasons. Was. That is, in the hollow fiber membrane filtration device, by improving the performance of the hollow fiber membrane module to reduce the number of modules, the diameter of the filtration tower can be reduced, and even if the number of filtration towers can be reduced, In the exchange type desalination equipment, the diameter of the desalination tower can be reduced and the number of filtration towers can be reduced by improving the performance of the ion exchange material so that the flow rate of water can be increased and reducing the packing amount. Even if it is possible, it is difficult to significantly reduce the required area of the device and reduce the cost because the improvement is limited to individual improvements in each device.

Incidentally, apart from the above-mentioned condensate treatment apparatus,
Several methods for simultaneously performing the filtration treatment and the desalination treatment have been proposed. For example, attempts have been made to apply reverse osmosis membrane technology to a condensate treatment device, but it has not yet reached practical use due to the following technical and economic problems. First, the water must pass through the reverse osmosis membrane for at least one
A pressure loss of about 0 kg / cm ² occurs. Therefore, the head of the pump that feeds water to the reverse osmosis membrane device is greatly increased, and the power cost is increased. Second, unlike filtration, it is difficult to increase the recovery rate of permeated water to 100% with a reverse osmosis membrane in terms of desalination performance. For this reason, a large amount of concentrated liquid is generated together with the permeated water, and the concentrated liquid cannot be discharged as it is, so that a separate concentrated liquid processing device is required. In addition, since the desalting performance is inferior to that of the ion exchange resin, a countermeasure is required.

As another method, Japanese Patent Application Laid-Open No. 61-47592 discloses a method using a hollow fiber membrane having an ion exchange function (hereinafter simply referred to as a composite hollow fiber membrane).
As proposed in JP-A-1-297149, etc.,
The following problems have been pointed out. First, there is a problem of ion exchange capacity and ion exchange capacity of the composite hollow fiber membrane. That is, since the durability of the hollow fiber membrane is reduced by adding an ion exchange group, and since the hollow fiber membrane is hollow and porous, a large amount of ions are formed at the same density as the packed layer of the ion exchange resin. It is technically impossible to add an exchange group to the hollow fiber membrane. Therefore, the ion exchange capacity per composite hollow fiber membrane is small. Also, unlike the case where the ion exchange layer is formed by mixing the granular cation resin and the anion resin, the composite hollow fiber membrane has a fixed cation exchange group and the anion exchange group because the membrane itself is fixed. It is difficult to establish a method for efficiently desalting both cations and anions in combination with a portion having the following formula, and it has not yet been put to practical use. When a composite hollow fiber membrane is used, a certain amount of space is provided between the hollow fiber membranes in order to maintain the filtration characteristics, and a protective cylinder that serves to protect the hollow fiber membrane in order to modularize the hollow fiber membrane. It is necessary to use a material other than the hollow fiber membrane. Further, since such a composite module is mounted in the tower, a considerably large space is required between the modules. For the above reasons,
Compared to an ion exchange layer densely packed with a granular ion exchange resin, the so-called volumetric efficiency of the ion exchange group is remarkably reduced, and the size of the column equipped with the composite hollow fiber membrane is increased. Therefore, when the composite hollow fiber membrane is applied to a large-capacity condensate treatment apparatus, the apparatus becomes extremely large.

Second, since the ion-exchange group is mounted on the fixed hollow fiber membrane, it is necessary to regenerate the ion-exchange group as it is. However, such a regeneration process is technically difficult and is still difficult. There is no established technology. Although a method of discarding without regenerating is also conceivable, since the ion exchange capacity of the composite hollow fiber membrane is originally small, the exchange life is short and the exchange cost is high.

Japanese Patent Application Laid-Open Nos. 64-67206 and 3-56126 disclose a composite hollow fiber membrane module in which a hollow fiber membrane module is filled with an ion exchange resin. Such problems have been pointed out. First, the ion exchange capacity per composite hollow fiber membrane module is small because the space for filling the ion exchange resin that can be secured in the hollow fiber membrane module is clearly limited. Therefore, when applied to a condensate desalination apparatus, the scale of the apparatus becomes extremely large as in the case of the composite hollow fiber membrane described above. Second, the flow rate passing through the ion-exchange resin layer becomes too fast, so that the desalination efficiency is reduced. Third
However, since the composite hollow fiber membrane module to which the ion exchange resin is fixed is filled, the regeneration of the ion exchange resin is technically difficult similarly to the above-described composite hollow fiber membrane. Therefore, it is necessary to take out the hollow fiber membrane module one by one from the filtration tower and replace it with a new ion exchange resin, or to discard the hollow fiber membrane part and replace it with a new one even though it can still be used.

As described above, several methods have been proposed as methods for simultaneously performing the filtration treatment and the desalination treatment, but all of them are possible in principle, but are inferior in functionality or require facilities. It must be said that this is a technology that has not yet been put to practical use because of its size.

In view of the above situation, an object of the present invention is to provide a water treatment apparatus that performs both filtration processing and desalination processing, particularly a water treatment apparatus that is suitable for condensate treatment at a nuclear power plant or the like. Another object of the present invention is to provide a device that is compact, requires a small installation area, and has low equipment costs as compared with a conventional water treatment device.

[0013]

As a result of studying the above-mentioned various methods, the present inventor has found that in order to achieve the above object, a conventional apparatus provided with a hollow fiber membrane filtration apparatus and an ion-exchange type desalination apparatus has been proposed. It was concluded that the water treatment system of the above should be improved as follows. Water treatment equipment, especially water treatment equipment installed for condensate treatment at nuclear power plants, reliably and continuously treats condensate to the required water quality for boiler water sent to the reactor for a long period of time. In particular, even when a large amount of seawater for steam cooling flows in due to breakage of a thin tube in the condenser, etc., impurities in seawater including ions are completely removed, and the reactor , Boiler, steam generator, etc. play an important role.
Therefore, it is essential that the water treatment device be based on reliable and proven technology that is technically established. Therefore, a hollow fiber membrane that has a high water flow rate and can reliably remove the clad efficiently is most suitable as the filter medium of the filtration device, and also has excellent ion removal capability and large ion exchange as a desalination device. The most technically reliable packed bed of ion exchange resins that has a capacity and is easy to regenerate is optimal. For the above reasons, the present inventor has realized a compact and integrated water treatment apparatus using a hollow fiber membrane filtration apparatus and an ion exchange desalination apparatus as one apparatus, and to solve the above-mentioned urgent problem. did.

Based on the above findings, in order to achieve the above-mentioned object, a combined filtration and desalination apparatus according to the present invention comprises an upper filtration chamber formed by dividing the inside of a vertical vessel into upper and lower parts by partition walls. And a desalination chamber below, and a hollow fiber membrane module is disposed in the filtration chamber so as to communicate with the desalination chamber inside the hollow fiber membrane, and the desalination chamber is filled with an ion exchange material. An ion-exchange layer was formed, the inlet of the water to be treated was provided on the vessel wall of the filtration chamber, and the outlet of the filtered and desalted treated water was provided on the vessel wall of the desalination chamber, and introduced into the filtration chamber. The water to be treated was permeated from the outside to the inside of each hollow fiber membrane, the permeated water was guided to a desalting chamber, the ion exchange layer was allowed to flow down from above, and the treated water was allowed to flow out from the outlet. It is characterized by:

The hollow fiber membrane module used in the present invention comprises:
As long as it has a bundle of hollow fiber membranes that can filter the water to be treated,
There is no restriction on the structure, dimensions, materials and the like of the hollow fiber membrane, and a known hollow fiber membrane module can be used. As the ion-exchange material, a renewable ion-exchange material, for example, a mixture of a known granular cation-exchange resin and an anion-exchange resin is preferably used, but other ion-exchange fibers can also be used. In addition, the specifications of the hollow fiber membrane module to be installed, the number thereof, the filling amount of the ion exchange material, the layer height of the ion exchange layer, the flow rate of the ion exchange layer, etc.
Good based on numbers. The combined filtration and desalination apparatus according to the present invention is not particularly limited in terms of the type of water to be treated, as long as it requires both filtration and desalination, and condensate obtained by condensing steam, especially nuclear power It is most suitable as a device for treating a large amount of condensate in places.

In a preferred embodiment of the present invention, the hollow fiber membrane module provided in the filtration chamber has a closed upper end and an open lower end, and passes through a through hole provided in a partition. The lower end is detachably fixed to the partition so as to communicate with the desalting chamber inside the hollow fiber membrane, and stands upright. This facilitates installation of the hollow fiber membrane module. Here, the “closed upper end portion”
Meaning that the upper end is closed so that permeated water does not flow out of the hollow fiber membrane module from the upper end, providing an opening through which fluid other than permeated water flows out, for example, providing an air vent nozzle to provide an upper end It does not prohibit the release of stagnant air. The “open lower end” means that the lower end has an opening so that the permeated water flows out of the hollow fiber membrane module from the lower end.

In another preferred embodiment of the present invention, the upper part of the filtration chamber is defined as a collection chamber for permeated water by a second partition wall extending in the transverse direction of the vertical vessel, and a desalination chamber is defined by a communication pipe. The hollow fiber membrane module disposed in the filtration chamber has an open upper end and a closed lower end, and is provided with a hollow fiber membrane through a through hole provided in the second partition. It is characterized by being detachably fixed to the second partition at the upper end so as to communicate with the water collecting chamber on the inside and being suspended. Here, the meanings of “open upper end” and “closed lower end” conform to the above definition.

In still another preferred embodiment of the present invention, the upper portion of the filtration chamber is defined as a permeated water collecting chamber by a second partition extending in the transverse direction of the vertical vessel, and is desalinated by a communication pipe. The hollow fiber membrane module, which communicates with the chamber and is disposed in the filtration chamber, has open ends and is removed inside the hollow fiber membrane through through holes provided in the partition and the second partition, respectively. It is characterized in that it is detachably fixed to the partition wall and the second partition wall at the upper end and the lower end so as to communicate with the salt chamber and the water collecting chamber, respectively.

In still another preferred embodiment of the present invention, the water collection chamber and the desalination chamber communicate with each other via a communication pipe disposed through a chamber defined by the partition and the second partition. It is characterized by doing.

In still another preferred embodiment of the present invention, a second outlet is provided in the water collecting chamber, and a shut-off valve is provided in the outlet of the desalting chamber, and the outlet of the desalting chamber is closed. It is characterized in that the permeated water is sent out from the second outlet.

In still another preferred embodiment of the present invention, a hollow fiber is provided with a cleaning mechanism for introducing gas to generate bubbles in water and dispersing the generated bubbles near the outer surface of each hollow fiber membrane. It is provided in a filtration chamber below the membrane module, and is characterized in that water is stirred by bubbles dispersed near the outer surface of each hollow fiber membrane to remove contaminants attached to the outer surface of the hollow fiber membrane. . Thus, at the end of the water flow, so-called scrubbing cleaning for removing contaminants such as clad attached to the outside of each hollow fiber membrane can be performed. The cleaning mechanism used in the present invention is not particularly limited in its configuration as long as it can remove contaminants on the hollow fiber membrane surface by bubble agitation. For example, the cleaning mechanism shown in detail in Examples below will be described. It can be mentioned as a preferred example. Further, the cleaning mechanism has a simple configuration in which an air supply pipe formed in a ring shape or a grid shape having an air ejection nozzle is provided at a lower portion of the filtration chamber, and the air ejection nozzle is arranged at a lower portion of the hollow fiber membrane module. It may be something.

[0022]

According to the present invention, a filtration chamber having a small hollow fiber membrane module capable of filtering a large flow rate with a small pressure loss and having a high desalting performance and a large ion exchange capacity is provided. By combining vertically and integrally a desalination chamber having an ion exchange layer filled with an ion exchange material that can be easily regenerated by the provided regenerating device, the filtration process can be performed reliably and efficiently. A highly reliable and compact water treatment device that performs both desalination treatments is realized. In addition, since the filtering device and the desalination device are integrated in one container, the number of containers is reduced by half compared to the conventional device, and the required installation area is greatly reduced. Since the length of the associated piping connecting the desalination device and the number of valves is reduced, the cost of parts and the amount of installation work are greatly reduced, and the overall equipment cost is reduced.

[0023]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below in more detail with reference to the accompanying drawings. Embodiment 1 FIG. 1 is a schematic sectional view showing the configuration of Embodiment 1 of a combined filtration and desalination apparatus according to the present invention. A combined filtration and desalination apparatus (hereinafter simply referred to as an apparatus) 10 of the present embodiment shown in FIG.
Is a combined water treatment device in which a filtration device and a desalination device are combined three-dimensionally up and down in one vertical container into one device, and is suitable as a condensate treatment device for a nuclear power plant, for example. It is used for The apparatus 10 includes an upper filtration chamber 16 and a lower desalination chamber 18 formed by dividing the inside of a vertical cylindrical container 12 into upper and lower parts by a mirror type partition wall 14.

The filtration chamber 16 is provided with a predetermined number of hollow fiber membrane modules 2 arranged so as to communicate with an inlet 19 for water to be treated provided on the vessel wall and the desalting chamber 18 inside the hollow fiber membrane.
0. As shown in FIG. 2, the hollow fiber membrane module 20 is a module in which a number of hollow fiber membranes 22 formed of a known permeable membrane are bundled to form a tube bundle. Hollow fiber membrane 2
The two tube bundles are fixed with adhesives or the like at the upper and lower ends with the hollow fiber membranes separated from each other (24A, 24B), and the outside is protected by an outer cylinder 26 having a large number of through holes 25 on the side. .
The upper end of the tube bundle of the hollow fiber membrane 22 is closed by an end plate 27, and the lower end passes through a water collecting tube 30 through a module water collecting chamber 28.
Is in communication with The module water collecting chamber 28 is formed by a lower end portion of the outer cylinder 26 and an upper end flange plate 31 of the water collecting pipe 30 joined to a periphery of the lower end portion.

Each of the water collecting pipes 30 penetrates the partition wall 14 and communicates with the desalting chamber 18, and has a common mounting seat (not shown).
Thereby, it is detachably fixed to the opening edge of the through hole 33 of the partition wall 14. Thereby, each hollow fiber membrane module 20
Can stand upright in the filtration chamber 16, and the water that has passed through each hollow fiber membrane 22 flows into the lower desalting chamber 18 via the water collecting pipe 30.

The filtration chamber 1 below the hollow fiber membrane module 20
A cleaning mechanism 34 is provided in the inside 6 to stir water by air bubbles and to remove contaminants such as clad adhered to the hollow fiber membrane.
Is provided. As shown in FIG. 2, the cleaning mechanism 34 includes an air chamber 38 formed by a partition plate 36 provided on the partition wall 14 through the water collection tube 30 and the partition wall 14, and a partition plate through the water collection tube 30. 36, a cylindrical portion 40 provided concentrically with the water collecting pipe 30 from the opening edge portion, and a plurality of fine holes or slits 42 provided in the circumferential direction of the cylindrical portion 40.
And an air supply port 44 provided in the container wall of the air chamber 38.
(See FIG. 1). With such a configuration, the air introduced into the air chamber 38 through the air supply port 44 is prevented from rising by the cylindrical portion 40 and stays in the upper portion of the air chamber 38, and becomes bubbles from the fine holes 42 to form bubbles in the cylindrical portion. 40 and water collecting pipe 30
Rises upward in the annular gap. When air is not introduced, the water to be treated flows through the annular gap between the water collecting pipe 30 and the cylindrical portion 40, so that the air chamber 38 is filled with the water to be treated.

On the other hand, the hollow fiber membrane module 20 is
6, a foam collection chamber 46 defined by a cylindrical skirt 32 and a water collection pipe 30 hanging from the outside, and a gap between the foam collection chamber 46 and the skirt 32 and the outer cylinder 26. 26
And an air introduction hole 50 that penetrates through the adhesive fixing portion 24B and exits to the outside of the hollow fiber membrane. When air is not introduced, the bubble collection chamber 46 and the air introduction hole 50 are filled with the water to be treated. With such a configuration, bubbles rising from the above-described pores 42 are
The air is introduced between the hollow fiber membranes 22 through the bubble collection chamber 46 and the air introduction hole 50. Thereafter, the bubbles are dispersed and each hollow fiber membrane 2
2 and vibrates each hollow fiber membrane 22 by agitating the water in the vicinity thereof to remove contaminants such as clad attached to the hollow fiber membrane 22 and recover the function of the hollow fiber membrane 22. Let it.

The hollow fiber membrane module that can be used in the present embodiment is provided with a bundle of hollow fiber membranes for filtering water to be treated, and is not limited to the above-described example, and is not limited in its configuration as long as it is an upright type. For example, as another example of the hollow fiber membrane module 20, a hollow fiber membrane module 120 shown in FIG. 5 that have the same functions as those in FIG. 2 are denoted by the same reference numerals, and description thereof will be omitted. The hollow fiber membrane module 120 is replaced with the end plate 27 of the hollow fiber membrane module 20, and the upper module collecting chamber 12 formed with a cap 122 at the upper end thereof.
And a communication pipe 126 that descends from the upper module water collecting chamber 124 at the center of the module and communicates with the lower module water collecting chamber 28. With such a configuration, the filtered water is collected from the upper part and the lower part, so that the amount of permeated water when the water to be treated passes through each hollow fiber membrane 22 becomes uniform in the length direction of the membrane. In addition, the hollow fiber membrane module 1
20 can also form a long module by connecting the hollow fiber membrane modules 120 one after another (but excluding the lower bubble introduction mechanism in this case) by relaying the upper module water collecting chamber 124 one after another. .

The desalting chamber 18 is provided below the water collecting pipe 30 of the hollow fiber membrane module 20, a rectifying plate 54, an ion exchange layer 56 formed below the rectifying plate 54, and provided on the bottom wall of the desalting chamber 18. And an outlet 58 for the treated water.
The rectifying plate 54 is a plate-like plate member and is provided to rectify and uniformly disperse the water flowing from the filtration chamber 16 via the water collecting pipe 30. Ion exchange layer 56
Is formed by filling a predetermined amount of a mixed resin of a regenerated cation exchange resin and an anion exchange resin, which is used in a conventional desalination apparatus. The ion exchange layer 56 is supported by a support member 60 including a mirror-shaped support plate 59 having a large number of holes, and a grid member 61 attached to each hole of the support plate 59. The grid member 61 has a number of slits of a size that allows water to pass but does not allow the ion exchange resin to pass, and the treated water flows down to the lower part of the desalting chamber 18 through the slit of the grid member 61.
Instead of being supported by the support member 60, the ion exchange layer 56 is supported by the bottom wall of the desalting chamber 18, and the ion exchange layer 56 is
A well-known ring-shaped water collecting mechanism may be provided in the inside, and the water collecting mechanism and the outlet 58 may be connected.

In FIG. 1, reference numeral 62 denotes an air vent nozzle provided at the top of the filtration chamber 16, 63 denotes an air vent nozzle for discharging air introduced during scrubbing cleaning, 64 denotes a drain nozzle provided at the bottom of the filtration chamber 16, and 66 denotes a drain nozzle. An air vent nozzle 68 provided at the upper part of the desalting chamber 18 is an inlet for ion exchange resin, has an internal pipe extending below the current plate 54, and 70 is an outlet for ion exchange resin. An internal pipe reaching the lower part of the ion exchange layer 56 is provided, and 72 is a drain nozzle of the desalting chamber 18. As shown in FIG. 1, the inlet 19 of the water to be treated, the air supply port 44, the air vent nozzles 62 and 63, the drain nozzle 64, the air vent nozzle 66, the ion exchange resin inlet 68, and the ion exchange resin outlet 70 Each of the drain nozzles 72 is provided with an on-off valve. Reference numeral 74 denotes a baffle plate that does not affect the hollow fiber membrane module 20 when the water to be treated flows into the filtration chamber 16. The drain nozzle 72
The drain nozzle may be branched from the water supply port 58 instead of providing the drain nozzle at the bottom of the desalting chamber 18.

In the first embodiment, the water to be treated flows into the filtration chamber 16 from the inlet 19 through the outer port 26 of the hollow fiber membrane module 20, and flows from the outside to the inside of each hollow fiber membrane 22. Suspended substances such as clad are trapped on the hollow fiber membrane surface while transmitting. The permeated water flows into the desalting chamber 18 via the water collecting pipe 30 of each hollow fiber membrane module 20, and the flow straightening plate 54
After the rectification and dispersion, the cations and anions are removed by flowing down the ion-exchange layer 56, flow out from the outlet 58, and are sent to the target place as treated water.

Hereinafter, a method of operating the apparatus 10 will be briefly described. When the operation of the apparatus 10 is started, first, a predetermined amount of the regenerated ion-exchange resin is mixed with water to increase the fluidity, and then is fed into the desalting chamber 18 from the inlet 68 of the ion-exchange resin. , An ion exchange layer 56 is formed. At this time, the air vent nozzle 66 is opened, the ion exchange resin is fed while the air in the desalting chamber 18 is being extracted, and the on-off valve of the nozzle 66 is closed when a predetermined amount of the ion exchange resin is fed. .
Next, the water to be treated is gradually introduced into the filtration chamber 16 from the inlet 19 while the air vent nozzle 62 is opened to extract air. When the water to be treated flows out of the air vent nozzle 62, the on-off valve of the nozzle 62 is closed, and the on-off valve of the outlet port 58 for treated water is opened to start water supply. Start. While the above-described processing is continued, when a suspended substance such as a clad is captured on the outer surface of the hollow fiber membrane 22 in the apparatus 10 and the pressure loss becomes large,
First, the outlet 58 and the inlet 19 of the treated water are closed,
Next, the air vent nozzle 63 of the filtration chamber 16 is opened, and the open / close valve of the air supply port 44 is opened to introduce air into the filtration chamber 16, and the hollow fiber membrane 22 is washed by the washing mechanism 34. After cleaning, the air vent nozzle 62 is opened, and then the drain nozzle 64 is opened to drain the drain. When regenerating or exchanging the ion exchange resin, the on-off valve of the ion exchange resin outlet 70 is opened to allow the ion exchange resin to flow out of the tower.

Embodiment 1 is configured as a combined filtration and desalination apparatus in which the filtration chamber 16 is provided on the desalination chamber 18.
The required installation area can be greatly reduced as compared with the conventional condensate treatment equipment. In addition, since two vertical vessels, which were conventionally required of a filtration tower and a desalination tower, are combined into one vertical vessel, the cost of the vessel itself and the cost of the foundation of the vessel can be reduced, and the filtration chamber can be reduced. And the desalination chamber are close to each other, so that the cost of piping for connecting them can be greatly reduced, and further, maintenance and inspection are easy.

Embodiment 2 FIG. 3 is a schematic sectional view showing the structure of Embodiment 2 of the combined filtration and desalination apparatus according to the present invention. The combined filtration and desalination apparatus of the present embodiment shown in FIG.
Is a composite water treatment apparatus in which a filtration device and a desalination device are combined three-dimensionally up and down in one vertical vessel in the same manner as in Example 1, and is, for example, a nuclear power plant. It is preferably used as a condensate treatment device. FIG.
1 and 2 which are the same as those shown in FIG. 1 and FIG. The device 78
Except for the configuration described below, the upper filtration chamber 16 is formed by dividing the inside of the vertical cylindrical container 12 into upper and lower parts by partition walls 14.
The apparatus is similar to the apparatus 10 in that the apparatus includes a desalination chamber 18 below, and the configuration of the desalination chamber 18 is substantially the same as that of the first embodiment.

In this embodiment, as shown in FIG. 2, the upper portion of the filtration chamber 16 is partitioned by a horizontal plate-shaped second partition wall 80, and the permeated water that has passed through the hollow fiber membrane module 84 is collected. The permeated water collecting chamber 82 is constituted. Second partition 80
The upper end of the hollow fiber membrane module 84 is removably fixed by a common mounting seat (not shown), and the hollow fiber membrane module 84 is supported in a suspended state. In FIG. 2, the hollow fiber membrane module 84
The upper end plate 27 is removed, and instead an end plate is attached below the adhesive fixing portion 24B at the lower end, whereby permeated water flows out from the upper end. 28 and water collecting pipe 30
The configuration is the same as that of the hollow fiber membrane module 20 shown in FIG. That is, the lower end of the hollow fiber membrane module 84 is provided only with the bubble collection chamber 46 defined by the skirt 32 and the lower end plate, and the bubble introduction mechanism including the air introduction hole 50 and the like. The hollow fiber membrane module 120 shown in FIG. 5 may be partially modified and used in the same manner as the hollow fiber membrane module 84.

As shown in FIG. 3, the cleaning mechanism 34 of this embodiment comprises a partition plate 36 provided on the partition 14 and a partition 14.
, A cylindrical portion 40 hanging down from the opening edge of the through hole of the partition plate 36, a large number of pores or slits 42 provided in the circumferential direction of the cylindrical portion 40, The cylindrical portion 40 is located inside the skirt 32 of the hollow fiber membrane module 84. The air supply port 44 is provided in the container wall. With such a configuration, the air introduced into the air chamber 38 through the air supply port 44 is prevented from rising by the cylindrical portion 40 and stays in the upper portion of the air chamber 38, and becomes bubbles from the fine holes 42 to form bubbles in the cylindrical portion. Go up in 40. The raised bubbles are introduced between the hollow fiber membranes 22 through the bubble collection chamber 46 and the air introduction holes 50 of the hollow fiber membrane module 84. Thereafter, the bubbles are dispersed and rise to the vicinity of each hollow fiber membrane 22, and the water in the vicinity is stirred to vibrate each hollow fiber membrane 22, and contaminants such as cladding adhered to the hollow fiber membrane 22. To recover the function of the hollow fiber membrane 22.

Each hollow fiber membrane module 84 is provided with a through hole 88 at a portion of the second partition wall 80 to which the upper end is fixed, and each hollow fiber membrane module 84 is connected to the hollow fiber membrane module through the through hole 88. The inside 22 communicates with the permeated water collecting chamber 82. Further, a transparent water catchment chamber 82 and desalting 18 so as to communicate, Oh at least one of the communication pipe 90 is provided to the partition wall 14 through the filter chamber 16 from the second partition wall 80
You. Further, an air vent nozzle 62 of the filtration chamber 16 is provided directly below the second partition wall 80, and an air vent nozzle 92 and a permeate outlet 94 are provided on the top wall of the permeated water collecting chamber 82, respectively.
Is provided. It should be noted that the air vent nozzle 92 of the water collecting chamber 82 is not provided on the top wall of the water collecting chamber 82, but instead is provided with an outlet 9 for the permeated water.
4 may be branched.

In the second embodiment, with the above structure, the water to be treated flows into the filtration chamber 16 from the inlet 19 and passes from the outside to the inside of each hollow fiber membrane 22 through the outer cylinder 26 of the hollow fiber membrane module 84. Suspended substances such as clad are trapped on the hollow fiber membrane surface while transmitting. The permeated water enters the permeated water collecting chamber 82 from the upper end of each hollow fiber membrane module 20 via the through hole 88, and further flows into the desalting chamber 18 via the communication pipe 90. In the desalination chamber 18, after being rectified and dispersed by the rectifying plate 54, the cations and anions are removed by flowing down the ion exchange layer 56, and flow out from the outlet 58 to be sent to the target place as treated water. You.

The operation of the apparatus 78 of the second embodiment is performed in accordance with the operation method of the apparatus 10 of the first embodiment. By bypassing the salt chamber 18, the permeated water obtained in the filtration chamber 16 can be directly sent to the outside from the permeated water outlet 94. Such a bypass operation of the desalination chamber 18 is performed at the time of starting operation of the power plant, when performing a preparatory operation for flushing (washing operation) with water or the like to clean the condensate system including the apparatus 78 of the present embodiment. Especially required. There is a case where the degree of vacuum of the condenser does not rise at the start of the power plant, so that a large amount of ionic impurities such as carbon dioxide in the air are mixed into the condensate and the ion exchange resin in the desalination chamber 18 is removed. This is because the ion exchange capacity is consumed. Therefore, the deionization chamber 18 is bypassed until the degree of vacuum of the condenser rises, and after the degree of vacuum is sufficiently increased, the bypass operation is stopped and the operation of feeding water to the desalination chamber 18 is performed, thereby performing ion exchange. This is because the ability of the resin can be used without waste. The second embodiment has the same effects as the first embodiment described above, and the configuration of the hollow fiber membrane module 84 is relatively simple as compared with the hollow fiber membrane module 20 of the first embodiment.

Third Embodiment FIG. 4 is a schematic sectional view showing the structure of a third embodiment of the combined filtration and desalination apparatus according to the present invention. A combined filtration and desalination apparatus (hereinafter simply referred to as an apparatus) 10 of the present embodiment shown in FIG.
Numeral 0 denotes a combined filtration and desalination apparatus as a combination of the first and second embodiments, which is suitably used, for example, as a condensate treatment apparatus for a nuclear power plant. 4 that are the same as those shown in FIGS. 1 to 3 are given the same reference numerals, and descriptions thereof will be omitted. The hollow fiber membrane module 102 used in the apparatus 100 is the same as the hollow fiber membrane module 20 except that the end plate 27 at the upper end is removed and the hollow portion of each hollow fiber membrane 22 is open at the upper end in FIG. It has the same configuration as. By using the hollow fiber membrane module 102 having such a configuration, the filtration chamber 1
6 has the same configuration as that of the second embodiment including the permeated water collecting chamber 82, and the lower portion of the filtration chamber 16 has the same configuration as the first embodiment. The configuration of the desalting chamber 18 is substantially the same as in the first and second embodiments.

In the third embodiment, the water to be treated flows into the filtration chamber 16 from the inlet 19 through the outer tube 26 of the hollow fiber membrane module 102 and flows from the outside to the inside of each hollow fiber membrane 22 by the above configuration. Suspended substances such as clad are trapped on the hollow fiber membrane surface while transmitting. Part of the permeated water enters the permeated water collecting chamber 82 from the upper end of each hollow fiber membrane module 20 via the through hole 88, and further flows into the desalination chamber 18 via the communication pipe 90, and The remainder of the water flows into the desalting chamber 18 from the lower end of each hollow fiber membrane module 20 via the water collecting pipe 30.
In the desalination chamber 18, after being rectified and dispersed by the rectifying plate 54, the cations and anions are removed by flowing down the ion exchange layer 56, and flow out from the outlet 58 to be sent to the target place as treated water. You.

In the third embodiment, as described above, the permeated water flows out from the upper end and the lower end of the hollow fiber membrane module 102, so that the water to be treated permeates through each hollow fiber membrane 22 of the hollow fiber membrane module 102. The amount of permeated water at the time becomes uniform in the length direction of the membrane. Therefore, one of the hollow fiber membrane modules 102
Since the permeated flow rate of permeated water is increased, Example 3 has a larger filtration flow rate as compared with Examples 1 and 2 if the same number of hollow fiber membrane modules is used, and the treated water has the same flow rate. If so, the number of hollow fiber membrane modules can be reduced. The operation of the apparatus 100 is performed according to the first and second embodiments.

[0043]

According to the present invention, a water treatment device is constituted by an upper filtration chamber and a lower desalination chamber formed by dividing the inside of a vertical vessel into upper and lower parts by partition walls. A hollow fiber membrane module is disposed inside the hollow fiber membrane so as to communicate with the desalting chamber, and an ion exchange layer filled with an ion exchange material is formed in the desalting chamber, so that the filtration apparatus and the desalting apparatus are desalted. This realizes a compact water treatment apparatus in which the apparatus is integrated into one container. In addition, the number of containers is greatly reduced as compared with the conventional apparatus, and since the filtering apparatus and the desalination apparatus are close to each other, maintenance and inspection are easy, and the required installation area is smaller than that of the conventional water treatment apparatus. The cost of the container itself and the costs associated with facilities such as container foundation, piping, valves, etc. can be reduced. As described above, the combined filtration and desalination apparatus according to the present invention is a water treatment apparatus suitable for condensate treatment, particularly for condensate treatment in a nuclear power plant or the like.

[Brief description of the drawings]

FIG. 1 is a schematic sectional view showing the configuration of a first embodiment of a combined filtration and desalination apparatus according to the present invention.

FIG. 2 is a schematic sectional view of a hollow fiber membrane module used in the embodiment of FIG.

FIG. 3 is a schematic sectional view showing a configuration of a second embodiment of a combined filtration and desalination apparatus according to the present invention.

FIG. 4 is a schematic sectional view showing the configuration of a third embodiment of the combined filtration and desalination apparatus according to the present invention.

FIG. 5 is a schematic sectional view of another example of the hollow fiber membrane module.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Example 1 of the complex type filtration and desalination apparatus according to the present invention 12 Vertical cylindrical container 14 Partition wall 16 Filtration chamber 18 Desalination chamber 19 Inlet 20 Hollow fiber membrane module 22 Hollow fiber membrane 24 Adhesive fixing part 25 Outer cylinder Through hole 26 outer cylinder 27 end plate 28 module water collecting chamber 30 water collecting pipe 31 upper end flange plate of water collecting pipe 32 skirt 33 through hole 34 cleaning mechanism 36 partition plate 38 air chamber 40 cylindrical portion 42 pore or nozzle 44 air supply port 46 Bubble collection chamber 50 Air introduction hole 54 Straightening plate 56 Ion exchange layer 58 Outlet 60 Support member 62, 63, 66, 92 Air vent nozzle 64, 72 Drain nozzle 68 Inlet for ion exchange resin 70 Outlet for ion exchange resin 74 Disturbance Plate 78 Example 2 of combined filtration and desalination apparatus according to the present invention 80 Second partition wall 82 Permeated water collecting chamber 84 Actual Hollow fiber membrane module used in Example 2 86 Partition plate 88 Through hole 90 Communication pipe 94 Delivery port 100 Example 3 of combined filtration and desalination apparatus according to the present invention 102 Hollow fiber membrane module used in Example 3 120 Hollow fiber Another example of the membrane module 122 Cap 124 Upper module water collection chamber 126 Communication pipe

Continuation of the front page (51) Int.Cl. ⁷ identification code FI G21F 9/06 511 G21F 9/06 511F ZAB ZAB (58) Investigated field (Int.Cl. ⁷ , DB name) C02F 1/44 B01D 63 / 02 B01J 47/02 G21D 1/02 G21F 9/06

Claims (6)

(57) [Claims] 1. A vertical vessel is provided with an upper filtration chamber and a lower desalination chamber formed by dividing the inside of a vertical vessel into upper and lower parts by partition walls. In the filtration chamber, a hollow fiber membrane module is provided inside the hollow fiber membrane. An ion exchange layer filled with an ion exchange material is formed in the desalination chamber so as to communicate with the desalination chamber. The outlet of the treated water was provided on the container wall of the desalting chamber, and the hollow fiber membrane module provided in the filtration chamber was closed.
It has an upper end and an open lower end, and is provided on a partition wall.
To the desalination chamber inside the hollow fiber membrane through the through hole
Is fixed to the partition wall at the lower end so as to be detachable, stands upright, allows the water to be treated introduced into the filtration chamber to permeate from the outside to the inside of each hollow fiber membrane, and further guides the permeated water to the desalting chamber for ion exchange. A combined filtration and desalination apparatus wherein the bed is caused to flow downward from above and the treated water is caused to flow out of the outlet. 2. The interior of a vertical container is vertically divided by a partition.
An upper filtration chamber and a lower desalination chamber are formed and a hollow fiber membrane module is desalted inside the hollow fiber membrane in the filtration chamber.
It is arranged so that it communicates with the deionization room.
An ion exchange layer is formed by filling
Filtration and desalination treatment at the inlet of the filtration chamber
Outlet of water are respectively provided on the container wall of the desalting compartment, the upper part of the filtration chamber is partitioned as catchment chamber permeate the second partition extending transversely of the vertical vessel, the Filtration chamber The arranged hollow fiber membrane module has an open upper end and a closed lower end, and communicates with the water collecting chamber inside the hollow fiber membrane through a through hole provided in the second partition. Fixed to the second partition at the upper end so as to be detachable, suspended, and the water collecting chamber and the desalination chamber were partitioned by the partition and the second partition.
The water to be treated introduced into the filtration chamber is communicated from the outside to the inside of each hollow fiber membrane through a communication pipe disposed through the chamber.
To collect the permeated water in the water collection chamber, and further through the communication pipe.
Falling down laterally of the ion exchange layer led to depletion chamber and from above
And let the treated water flow out from the outlet
A combined filtration and desalination apparatus, characterized in that: 3. The inside of a vertical container is vertically divided by a partition.
An upper filtration chamber and a lower desalination chamber are formed and a hollow fiber membrane module is desalted inside the hollow fiber membrane in the filtration chamber.
It is arranged so that it communicates with the deionization room.
An ion exchange layer is formed by filling
Filtration and desalination treatment at the inlet of the filtration chamber
Outlet of water are respectively provided on the container wall of the desalting compartment, the upper part of the filtration chamber is partitioned as catchment chamber permeate the second partition extending transversely of the vertical vessel, the Filtration chamber The disposed hollow fiber membrane module has open both ends, and communicates with the desalination chamber and the water collecting chamber inside the hollow fiber membrane through through holes provided respectively in the partition and the second partition. The upper and lower ends are detachably fixed to the partition wall and the second partition wall, respectively, and the water to be treated introduced into the filtration chamber is supplied from the outside to the inside of each hollow fiber membrane.
To the desalination chamber,
The remaining excess water is collected in the water collection chamber, and is connected to the desalination chamber via the communication pipe.
Guide the ion-exchange layer down from above and process
The feature is that the water flows out from the outlet
Composite filtration desalter to. 4. The water collection chamber and the desalination chamber communicate with each other via a communication pipe disposed through a chamber defined by the partition and the second partition. composite filtration desalination apparatus according to 3. 5. A second outlet in the water collecting chamber and a shut-off valve in the outlet of the desalting chamber, and the outlet of the desalting chamber is closed to transmit permeated water from the second outlet. The combined filtration and desalination apparatus according to any one of claims 2 to 4, wherein: 6. A gas is introduced to generate bubbles in water,
A washing mechanism that disperses generated bubbles near the outer surface of each hollow fiber membrane is provided in the filtration chamber below the hollow fiber membrane module, and water is stirred by the bubbles dispersed near the outer surface of each hollow fiber membrane. The combined filtration and desalination apparatus according to any one of claims 1 to 5 , wherein contaminants attached to the outer surface of the hollow fiber membrane are peeled off.